Masking methods during semiconductor device fabrication

ABSTRACT

A method of removing an oxide mask during fabrication of semiconductor devices which includes providing a providing a III-V compound semiconductor substrate having a surface, the surface having a growth area and a masked area masked by an oxide film formed on the surface thereof. The oxide film is removed with a Trisdimethylamino group V compound.

FIELD OF THE INVENTION

The present invention pertains to the fabrication of semiconductor devices and more specifically to improved masking techniques during semiconductor device fabrication.

BACKGROUND OF THE INVENTION

In the semiconductor field it is common to sequentially grow several different layers of semiconductor material and use various masks and etching steps to form the desired devices and terminals on the devices. In some methods, masking material, e.g. nitride/oxide or the like, is applied and semiconductor material is grown over masked and unmasked areas. The material on the masked areas is then removed by etching and lift-off. In some instances material is selectively grown in unmasked areas and the masking material is then removed. In some processes a photoresist mask is used to define and develop a hard mask, i.e. a metal mask, a nitride mask, etc.

Generally, in these prior art methods of fabricating semiconductor devices, etching is required to remove unwanted material and masks are removed by etching, solvent, or the like. During the etching and/or mask removal processes, the material of the semiconductor device has a high likelihood of being contaminated by the etchant, which contamination greatly reduces the life of the device, the operating characteristics of the device, and the reliability of the device. Further, the etching process severely damages semiconductor material adjacent the etched areas which further reduces life, operating characteristics, and reliability. Also, etching processes are very time consuming and difficult to perform.

Thus, these prior art techniques involve many process steps such as resist spinning, exposure, developing, cleaning and so on. All of these processes can introduce contamination, decrease yield, etc. A further problem that arises is that the structure or substrate (generally a wafer) must be removed from the growth chamber to remove the masking material. The structure is then masked again and reintroduced into the growth chamber for re-growth. Thus, the prior art techniques keep the wafer vacuum incompatible.

In addition to the masking and etching problems, all known prior art fabrication processes require many interspersed growing, masking and etching steps which greatly complicate and lengthen the process. For example, when epitaxial layers are grown, the wafers must be placed in a vacuum or pressure chamber to provide the atmosphere for the growth. Each time the wafer must be etched and/or masked, it must be removed from the chamber, resulting in large amounts of preparation time for each step. Also, each time wafers are removed from a chamber and subsequently replaced, the opening and preparation of the chamber (as well as the processing of the wafer) is an opportunity for additional impurities and contaminants to be introduced to the wafer.

Accordingly, it would be highly desirable to provide fabrication methods for semiconductor devices with improved masking processes.

It is a purpose of the present invention to provide a new and improved method of masking gallium arsenide substrates during semiconductor device fabrication.

It is another purpose of the present invention to provide a new and improved method of masking gallium arsenide substrates during the fabrication of semiconductor devices which does not require removal of the substrate from the processing chamber to remove the mask.

It is still another purpose of the present invention to provide a new and improved method of masking gallium arsenide substrates during the fabrication of semiconductor devices which does not require the introduction of contaminants, such as photoresist, solvents and etchants.

It is a further purpose of the present invention to provide a new and improved method of masking gallium arsenide substrates during the fabrication of semiconductor devices which is much simpler and includes less chance of contamination of the devices.

And a further purpose of the present invention is to reduce the temperature to which the substrate is exposed, to perform the masking steps.

Another purpose of the present invention is to provide a new and improved method of masking gallium arsenide substrates wherein the mask is removed at conditions similar to growth, with small changes in chemistry.

Still another purpose of the present invention is to provide a new and improved method of masking gallium arsenide substrates wherein the mask is removed, enabling regrowth, without significantly etching or contaminating the grown epilayer.

Yet another purpose of the present invention is to provide a new and improved method of masking gallium arsenide substrates enabling the mask to be without changing the gases used for regrowth.

SUMMARY OF THE INVENTION

Briefly, to achieve the desired objects of the instant invention in accordance with a preferred embodiment thereof, provided is a method of removing an oxide mask during fabrication of semiconductor devices which includes providing a III-V compound semiconductor substrate having a surface, the surface having a growth area and a masked area masked by an oxide film formed on the surface thereof. The oxide film is removed with a Trisdimethylamino group V compound.

Also provided is a method of masking surfaces during fabrication of semiconductor devices which includes providing a gallium arsenide substrate, or other III-V compounds, with or without a layer of native oxide thereon. A metal mask is positioned on the surface so as to define a growth area and an unmasked portion on the surface. Ultraviolet light is directed at the unmasked area, by exposing the surface to a bright light, so as to grow an oxide film on the unmasked portion of the surface. The metal mask is removed and the oxide film then serves as a mask for further operations and can be easily removed in situ at low temperature by etching with Trisdimethylamino group V compounds. Subsequent to the growth of required compounds in the native oxide regions, the native oxide is removed by heating and the masking oxide is removed by etching.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and further and more specific objects and advantages of the instant invention will become readily apparent to those skilled in the art from the following detailed description of a preferred embodiment thereof taken in conjunction with the drawings, in which:

FIGS. 1-4 are simplified sectional views of a substrate illustrating several sequential steps in a masking process in accordance with the present invention;

FIG. 5 is a simplified sectional view of the substrate of FIG. 4 with semiconductor material grown on the surface;

FIG. 6 is a simplified sectional view of the substrate with the mask removed; and

FIG. 7 is a simplified sectional view of the substrate illustrating additional material deposited thereon.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Turning now to the drawings in which like reference characters indicate corresponding elements throughout the several views, attention is first directed to FIGS. 1-4 which illustrate several steps in a method of masking a gallium arsenide substrate 10, in accordance with the present invention, for the fabrication of semiconductor devices. It should be understood that gallium arsenide substrate 10 is utilized herein for purposes of this description but other III-V compounds and other semiconductor materials may be utilized in other applications. Referring specifically to FIG. 1, a simplified sectional view of gallium arsenide substrate 10 having a surface 11 is illustrated. It should be understood that substrate 10 might simply be a supporting structure, such as a wafer or the like, or it might include various layers formed on or in the supporting structure.

Surface 11 of gallium arsenide substrate 10 has a film 12 (generally 20 angstroms or less) of a native oxide which, as is well known in the art, forms generally instantaneously upon exposure to air. It should be understood that the native oxide is not always necessary to the present invention and is only illustrated because it is generally present and requires special procedures to prevent. In some applications various types of passivation may be used, to prevent the formation of film 12, in which case such passivation may have to be removed before the present procedure can be performed. It has been found that the present technique will operate generally as described with the surface simply being clean (i.e. no foreign matter).

A mask 15 is positioned adjacent to surface 11 of substrate 10 for patterning surface 11, as will be explained presently. Mask 15 generally is a shadow or metal mask but, in some special applications, it can be formed in the well known manner with photolithography as in an aligner or stepper (generally includes a projected image from a mask). As will become apparent presently, one of the major advantages of the present technique is that photolithography and the like are not necessary for the described masking operations. In a preferred embodiment, mask 15 is a mask plate with metal lines and other features, for example, a chrome mask. In any case, mask 15 is positioned adjacent surface 11 so as to define one or more growth areas 16 on surface 11 beneath mask 15 and one or more unmasked portions 17 on surface 11 of substrate 10.

Unmasked portions 17 of surface 11 are exposed to a bright light preferably including deep ultraviolet, represented by arrows 21 in FIG. 2. The bright light may be, for example, the type typically used in aligners, steppers, or E-beam devices in the semiconductor industry. The term "deep ultraviolet" refers to light in the ultraviolet range, generally with a wavelength in the range of 180 to 250 nanometers. In the present specific example, it is believed that the 185 nm light generates ozone due to optical excitation. Therefore, excitation wavelength that is most suitable for efficient ozone generation is also the most efficient to use, although virtually any ultraviolet light will produce the desired result. It is believed that exposure to other wavelengths, such as 248 nm in a specific example, modifies the composition of the surface oxide by forming a different kind of oxide or complex oxide molecules that are more stable than the native oxide. The exposure to light can be performed under a lamp. However, when the light is collimated, as in an aligner or stepper, sharp features can be defined in unmasked portion 17.

In a specific example, a gallium arsenide wafer with a layer of native oxide on the surface was provided. Standard bright lights, both at 185 nm and at 248 nm, were used with the wafer being exposed through a chrome coated mask for 5 minutes. An oxide film with a thickness less than approximately 2 nm was produced in the unmasked areas.

Once oxide film 20 is grown, mask 15 is removed to expose growth areas 16, as illustrated in FIG. 3. Oxide film 20 then serves as a mask for further process operations, such as growth, etching, and so on, and can be easily removed in situ as will be discussed presently. As an example of further operations, substrate 10 is then introduced into a growth chamber (not shown) and heated to a temperature of approximately 580° C. to desorb any native oxide that may still be present in growth areas 16. Substrate 10 with native oxide-free growth areas 16 is illustrated in FIG. 4.

While retaining substrate 10 in the growth chamber, selective growth of crystalline, or semiconductor, material 25 in growth areas 16 is performed, as illustrated in FIG. 5. With oxide film 20 in place as a mask for further growth, a predetermined amount of crystalline material 25 is selectively grown in area (or areas) 16. For purposes of this disclosure, "selective growth" or "selectively grown" is defined as growing only in the specific or designated area. In a specific example, selective InAs was selectively grown using trimethyl indium and arsine in a chemical beam epitaxy. Thus, in this example, material 25 grows only in growth areas 16. Further, material 25 generally grows in a crystalline form so that growth rates and shapes are crystallographic dependent, i.e. the rate and shape of growth are dependent upon the type of material 25 being utilized.

Once the desired amount of material 25 is grown in growth areas 16, oxide film 20 can be removed. While oxide film 20 can be removed by such techniques as thermal desorption, ECR plasma or RF plasma in the growth chamber, each requires temperatures which are best avoided. For example, in thermal desorption, substrate 10 is heated to a higher temperature (approximately, 640° C.) in the growth chamber to desorb oxide film 20, resulting in the structure illustrated in FIG. 6. While extremely useful, lower temperatures are preferred to prevent damage or degradation to the device. To remove the oxide film in accordance with the present invention, a Trisdimethylamino group V compound is used. It has been found that these compounds will remove the oxide film formed on III-V compound semiconductor materials at temperatures much below the temperatures required for desorption. Thus, the mask utilized for patterned growth of material 25 is removed, in situ, i.e. without the need to remove substrate 10 from the growth chamber at very low temperatures.

TDMAA has also been used for the growth of arsenic based compounds. In some specific applications of this process, the inlet temperature can be changed and the TDMAA can be used as an etchant to remove the growth mask. In this process some small amount of the regrown material may also be etched during the mask removal, which limits the usefulness of this process somewhat to specific applications. Thus, the present method can be used where some group V materials are used not only to grow semiconductor/etch semiconductor but also to remove the mask, hence enabling regrowth.

Further growth of material can be performed on crystalline material 25 subsequent to the step of removing oxide film 20. As illustrated in FIG. 7, a layer 30 of additional material is grown or deposited on the surface of material 25 and on the exposed surface of substrate 10. Thus, re-growth is performed without having to remove substrate 10 from the growth chamber or change the arsenic species. Thus, the present method enables the fabrication of embedded structures (e.g. material 25 in FIG. 7) in semiconductor devices by allowing the removal of the mask insitu and at low temperatures. It will be apparent to those skilled in the art, after reading this disclosure, that complete semiconductor devices can be formed on substrate 10 without removing it from the growth chamber.

Thus, an improved masking processes is disclosed which provides a new and improved method of masking gallium arsenide substrates during semiconductor device fabrication. The new and improved method of masking gallium arsenide substrates includes a simplified masking method without requiring photoresists, deposited nitride/oxide, and the like. The absence of resist in the process improves resolution limits previously defined by resist thickness. Further, the new process eliminates a number of process steps and, hence, is cheaper, cleaner, improves yield, can result in better resolution and therefore smaller lines, and makes the fabrication process vacuum compatible. Also, the oxide layer can be used as an etch mask or for any other semiconductor processes that require masking, and can be removed in situ at low temperatures.

Because the new and improved method of masking gallium arsenide substrates does not require the introduction and removal of wafers or substrates from processing chambers several times in sequence during the fabrication of semiconductor devices, the fabrication process is much simpler and includes less chance of contamination of the devices. The present novel process allows selective growth and further re-growth, all in-situ, without exposure to air and contamination during the intermediate processing steps between epitaxy, etc. By eliminating air and other contaminant exposure between steps, the novel process ensures good quality in subsequent epitaxial steps.

While we have shown and described specific embodiments of the present invention, further modifications and improvements will occur to those skilled in the art. We desire it to be understood, therefore, that this invention is not limited to the particular forms shown and we intend in the appended claims to cover all modifications that do not depart from the spirit and scope of this invention. 

What is claimed is:
 1. A method of masking surfaces during fabrication of semiconductor devices comprising the steps of:providing a III-V compound semiconductor substrate with a surface; positioning a mask on the surface so as to define a growth area and a mutually exclusive unmasked portion on the surface; directing ultraviolet light onto the unmasked portion of the surface to grow an ultraviolet oxide film on the unmasked portion of the surface; removing the mask and introducing the substrate into a growth chamber and selectively growing, utilizing a Trisdimethylamino group V compound, on the exposed growth area, a crystalline compound semiconductor material utilizing the ultraviolet oxide film as a mask; and removing the ultraviolet oxide film in situ in the growth chamber with the Trisdimethylamino group V compound.
 2. A method as claimed in claim 1 wherein the step of providing a substrate includes providing a gallium arsenide substrate.
 3. A method as claimed in claim 2 wherein the step of removing the oxide film includes removing the oxide film with Trisdimethylaminoarsine.
 4. A method of masking surfaces during fabrication of semiconductor devices comprising the steps of:providing a III-V compound semiconductor substrate with a surface having a native oxide thereon; positioning a mask on the surface so as to define a growth area and a mutually exclusive unmasked portion on the surface; directing ultraviolet light onto the unmasked portion of the surface to grow an ultraviolet oxide film on the unmasked portion of the surface; removing the mask and introducing the substrate into a growth chamber and heating the substrate to a first temperature to desorb the native oxide in the growth area; selectively growing, on the exposed growth area, a crystalline material utilizing the ultraviolet oxide film as a mask; removing the ultraviolet oxide film in situ in the growth chamber with a Trisdimethylamino group V compound; and in situ in the growth chamber, growing at least one additional layer of crystalline compound semiconductor material on the unmasked portion of the surface.
 5. A method as claimed in claim 4 wherein the step of providing a substrate includes providing a gallium arsenide substrate.
 6. A method as claimed in claim 5 wherein the step of removing the oxide film includes removing the oxide film with Trisdimethylaminoarsine. 